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T HE P HYSICS OF F OAM. Boulder School for Condensed Matter and Materials Physics July 1-26, 2002: Physics of Soft Condensed Matter 1. Introduction Formation Microscopics 2. Structure Experiment Simulation 3. Stability Coarsening Drainage 4. Rheology Linear response
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THEPHYSICS OF FOAM • Boulder School for Condensed Matter and Materials Physics July 1-26, 2002: Physics of Soft Condensed Matter 1. Introduction Formation Microscopics 2. Structure Experiment Simulation 3. Stability Coarsening Drainage 4. Rheology Linear response Rearrangement & flow Douglas J. DURIAN UCLA Physics & Astronomy Los Angeles, CA 90095-1547 <durian@physics.ucla.edu>
Foam is… • …a random packing of bubbles in a relatively small amount of liquid containing surface-active impurities • Four levels of structure: • Three means of time evolution: • Gravitational drainage • Film rupture • Coarsening (gas diffusion from smaller to larger bubbles)
Foam is… • …a most unusual form of condensed matter • Like a gas: • volume ~ temperature / pressure • Like a liquid: • Flow without breaking • Fill any shape vessel • Under large force, bubbles rearrange their packing configuration • Like a solid: • Support small shear forces elastically • Under small force, bubbles distort but don’t rearrange
Foam is… • Everyday life: • detergents • foods (ice cream, meringue, beer, cappuccino, ...) • cosmetics (shampoo, mousse, shaving cream, tooth paste, ...) • Unique applications: • firefighting • isolating toxic materials • physical and chemical separations • oil recovery • cellular solids • Undesirable occurrences: • mechanical agitation of multicomponent liquid • pulp and paper industry • paint and coating industry • textile industry • leather industry • adhesives industry • polymer industry • food processing (sugar, yeast, potatoes) • metal treatment • waste water treatment • polluted natural waters • need to control stability and mechanics • must first understand microscopic structure and dynamics… • familiar! • important!
Condensed-matter challenge • To understand the stability and mechanics of bulk foams in terms of the behavior at microscopic scales bubbles are the “particles” from which foams are assembled • Easy to relate surfactant-film and film-bubble behaviors • Hard to relate bubble-macro behavior • Opaque: no simple way to image structure • Disordered: no periodicity • kBT << interaction energy: no stat-mech. • Flow beyond threshold: no linear response • hard problems! • new physics!
Jamming • Similar challenge for seemingly unrelated systems • Tightly packed collections of bubbles, droplets, grains, cells, colloids, fuzzy molecules, tectonic plates,.… • jammed/solid-like: small-force / low-temperature / high-density • fluid/liquid-like: large-force / high-temperature / low-density force-chains (S. Franklin) avalanches (S.R. Nagel) universality?
Foam Physics Today • visit the websites of these Summer 2002 conferences to see examples of current research on aqueous foams • Gordon Research Conference on Complex Fluids • Oxford, UK • EuroFoam 2002 • Manchester, UK • Foams and Minimal Surfaces • Isaac Newton Institute for Mathematical Sciences • Geometry and Mechanics of Structured Materials • Max Planck Institute for the Physics of Complex Systems • after these lectures, you should be in a good position to understand the issues being addressed & progress being made!
General references • D. Weaire and N. Rivier, “Soap, cells and statistics - random patterns in two dimensions,” Contemp. Phys. 25, 55 (1984). • J. P. Heller and M. S. Kuntamukkula, “Critical review of the foam rheology literature,” Ind. Eng. Chem. Res. 26, 318-325 (1987). • A. M. Kraynik, “Foam flows,” Ann. Rev. Fluid Mech. 20, 325-357 (1988). • J. H. Aubert, A. M. Kraynik, and P. B. Rand, “Aqueous foams,” Sci. Am. 254, 74-82 (1989). • A. J. Wilson, ed., Foams: Physics, Chemistry and Structure (Springer-Verlag, New York, 1989). • J. A. Glazier and D. Weaire, “The kinetics of cellular patterns,” J. Phys.: Condens. Matter 4, 1867-1894 (1992). • C. Isenberg, The Science of Soap Films and Soap Bubbles (Dover Publications, New York, 1992). • J. Stavans, “The evolution of cellular structures,” Rep. Prog. Phys. 56, 733-789 (1993). • D. J. Durian and D. A. Weitz, “Foams,” in Kirk-Othmer Encyclopedia of Chemical Technology, 4 ed., edited by J.I. Kroschwitz (Wiley, New York, 1994), Vol. 11, pp. 783-805. • D. M. A. Buzza, C. Y. D. Lu, and M. E. Cates, “Linear shear rheology of incompressible foams,” J. de Phys. II 5, 37-52 (1995). • R. K. Prud'homme and S. A. Khan, ed., Foams: Theory, Measurement, and Application. Surfactant Science Series 57, (Marcel Dekker, NY, 1996). • J.F. Sadoc and N. Rivier, Eds. Foams and Emulsions (Kluwer Academic: Dordrecht, The Netherlands, 1997). • D. Weaire, S. Hutzler, G. Verbist, and E. Peters, “A review of foam drainage,” Adv. Chem. Phys. 102, 315-374 (1997). • D. J. Durian, “Fast, nonevolutionary dynamics in foams,” Current Opinion in Colloid and Interface Science 2, 615-621 (1997). • L.J. Gibson and M.F. Ashby, Cellular Solids: Structure and Properties (Cambridge University Press, Cambridge, 1997). • M. Tabor, J. J. Chae, G. D. Burnett, and D. J. Durian, “The structure and dynamics of foams,” Nonlinear Science Today (1998). • D. Weaire and S. Hutzler, The Physics of Foams (Clarendon Press, Oxford, 1999). • S.A. Koehler, S. Hilgenfeldt, and H.A. Stone, "A generalized view of foam drainage,” Langmuir16, 6327-6341 (2000). • A.J. Liu and S.R. Nagel, eds., Jamming and Rheology (Taylor and Francis, New York, 2001). • J. Banhart and D. Weaire, “On the road again: Metal foams find favor,” Physics Today 55, 37-42 (July 2002). Thanks for the images: John Banhart, Ken Brakke, Jan Cilliers, Randy Kamien, Andy Kraynik, John Sullivan, Paul Thomas, Denis Weaire, Eric Weeks,…
special thanks to collaborators • Students • Alex Gittings • Anthony Gopal • Pierre-Anthony Lemieux • Rajesh Ojha • Ian Ono • Sidney Park • Moin Vera • Postdocs • Ranjini Bandyopadhyay • Narayanan Menon • Corey O’Hern • Arnaud Saint-Jalmes • Shubha Tewari • Loic Vanel • Colleagues • Chuck Knobler • Steve Langer • Andrea Liu • Sid Nagel • Dave Pine • Joe Rudnick • Dave Weitz
gas foam gas bubble raft foam solution porous plate gas Foam production I. • Shake, blend, stir, agitate, etc. • Uncontrolled / irreproducible • Unwanted foaming of multicomponent liquids • Sparge = blow bubbles • Polydisperse or monodisperse • Uncontrolled/non-uniform liquid fraction
Foam production II. • in-situ release / production of gas • nucleation • eg CO2 in beer • aerosol: • eg propane in shaving cream • small bubbles! • active: • eg H2 in molten zinc • eg CO2 from yeast in bread
foam jet solution gas Foam production III. • turbulent mixing of thin liquid jet with gas • vast quantities • small polydisperse bubbles • controlled liquid fraction • lab samples • firefighting • distributing pesticides/dyes/etc. • covering landfills • supressing dust • …
Foam production IV. • many materials can be similarly foamed • nonaqueous liquids (oil, ferrofluids,…) • polymers (styrofoam, polyurethane,…) • metals • glass • concrete • variants found in nature • cork • bone • sponge • honeycomb
Foams produced by animals • spittle bug: • cuckoo spit / froghoppers: • stickleback-fish’s nest
Foam production V. • antifoaming agents • prevent foaming or break an existing foam • mysterious combination of surfactants, oils, particles,…
Microscopic behavior • look at progressively larger length scales… • surfactant solutions • soap films • local equilibrium & topology
Pure liquid • bubbles quickly coalesce – no foam • van der Waals force prefers monotonic dielectric profile; therefore, bubbles attract: a b a “effective interface potential” is free energy cost per unit area: Vvdw(l)= -A/12pl2, A=Hamaker constant l l
80 erg/cm2 surface tension, s 30 erg/cm2 CMC Log [surfactant concentation, c] Surfactant solution • surface active agent – adsorbs at air/water interface • head: hydrophilic (eg salt) • tail: hydrophobic (eg hydrocarbon chain) • lore for good foams… • chain length: short enough that the surfactant is soluble • concentration: just above the “critical micelle concentration” • eg sodium dodecylsulfate (SDS) {NB: lower s doesn’t stabilize the foam…}
- - + + + + + + + + + + + + + + + + - - - - - - - - - - - - - - Electrostatic “double-layer” • adsorbed surfactants dissociate, cause repulsion necessary to overcome van der Waals and hence stabilize the foam • electrostatic • entropic (dominant!) • NB: This is similar to the electrostatic stabilization of colloids free energy cost per unit area: VDL(l)= (64kBTr/KD)Exp[-KDl], r = electrolyte concentration KD-1 ~ r-1/2 = Debye screening length
thickness, l Soap film tension • film tension / interface potential / free energy per area: g(l) = 2s + VVDW(l) + VDL(l) ~ 2s • disjoining pressure: P(l) = -dg/dl • vanishes at equilibrium thickness, leq ~ KD-1 (30-3000Å)
Film junctions • Plateau border • scalloped-triangular channel where three films meet • the edge shared by three neighboring bubbles • Vertex • region where four Plateau borders meet • the point shared by four neighboring bubbles
Liquid distribution • division of liquid between films-borders-vertices • repulsion vs surface tension • wet vs dry Prepulsion dominates => maximize l s dominates => minimize area dry => polyhedral wet => spherical
Laplace’s law • the pressure is greater on the inside a curved interface • due to surface tension, s = energy / area = force / length • forces on half-sphere: • SFup = Pipr2 – Popr2 – 2psr = 0 • energy change = pressure x volume change: • dU = (DP)4pr2dr, where U(r)=4pr2s s {in general, DP= s(1/r1+1/r2)} Pi = Po + 2s/r r Po s Pi
Liquid volume fraction • liquid redistributes until liquid pressure is same everywhere • typically: film thickness l << border radius r << bubble radius R • liquid volume fraction scales as e ~ (lR2 + r2R + r3)/R3 ~ (r/R)2 • most of the liquid resides in the Plateau borders • PB’s scatter light… • PB’s provide channel for drainage… l Pfilm = Pgas + P(l) Pborder = Pgas + s/r bubble radius, R r
Plateau’s rules for dry foams • for mechanical equilibrium: • i.e. for zero net force on a Plateau border, • zero net force on a vertex, • and SDP=0 going around a closed loop: (1) films have constant curvature & intersect three at a time at 120o (2) borders intersect four at a time at cos-1(1/3)=109.47o • rule #2 follows from rule #1 • both are obviously correct if the films and borders are straight: P P SF=0 P
Plateau border in/out of page r1 r2 r3 Rule #1 for straight borders • choose r1 and orientation of equilateral triangle • construct r2 from extension down to axis • construct r3 from inscribed equilateral triangle • NB: centers are on a line • films meet at 120o (triangles meet at 60o-60o-60o, and are normal to PB’s) • similar triangles give (r1+r2)/r1 = r2/r3, i.e. 1/r1 + 1/r2 = 1/r3 and so SP=0
Curved Plateau borders • proof of Plateau’s rules is not obvious! • established in 1976 by Jean Taylor
Decoration theorem for wet foams • for d=2 dimensions, an equilibrium wet foam can be constructed by decorating an equilibrium dry foam • can you construct an elementary proof? • PB’s are circular arcs that join tangentially to film • theorem fails in d=3 due to PB curvature
Next time… • periodic foam structures • disordered foam structures • experiment • simulation